Analysis and Control of a Continuous-Time Bi-Virus Model

Ji Liu; Philip E. Pare; Angelia Nedich; Choon Yik Tang; Carolyn L. Beck; Tamer Basar

doi:10.1109/TAC.2019.2898515

Analysis and Control of a Continuous-Time Bi-Virus Model

Ji Liu, Philip E. Pare, Angelia Nedich, Choon Yik Tang, Carolyn L. Beck, Tamer Basar

Research output: Contribution to journal › Article › peer-review

Abstract

This paper studies a distributed continuous-time bi-virus model in which two competing viruses spread over a network consisting of multiple groups of individuals. Limiting behaviors of the network are characterized by analyzing the equilibria of the system and their stability. Specifically, when the two viruses spread over possibly different directed infection graphs, the system may have the following: first, a unique equilibrium, the healthy state, which is globally stable, implying that both viruses will eventually be eradicated, second, two equilibria including the healthy state and a dominant virus state, which is almost globally stable, implying that one virus will pervade the entire network causing a single-virus epidemic while the other virus will be eradicated, or third, at least three equilibria including the healthy state and two dominant virus states, depending on certain conditions on the healing and infection rates. When the two viruses spread over the same directed infection graph, the system may have zero or infinitely many coexisting epidemic equilibria, which represents the pervasion of the two viruses. Sensitivity properties of some nontrivial equilibria are investigated in the context of a decentralized control technique, and an impossibility result is given for a certain type of distributed feedback controller.

Original language	English (US)
Article number	8638525
Pages (from-to)	4891-4906
Number of pages	16
Journal	IEEE Transactions on Automatic Control
Volume	64
Issue number	12
DOIs	https://doi.org/10.1109/TAC.2019.2898515
State	Published - Dec 2019

Keywords

Competing viruses
computer viruses
epidemic processes
networked control systems
nonlinear control systems

ASJC Scopus subject areas

Control and Systems Engineering
Computer Science Applications
Electrical and Electronic Engineering

Online availability

10.1109/TAC.2019.2898515

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title = "Analysis and Control of a Continuous-Time Bi-Virus Model",

abstract = "This paper studies a distributed continuous-time bi-virus model in which two competing viruses spread over a network consisting of multiple groups of individuals. Limiting behaviors of the network are characterized by analyzing the equilibria of the system and their stability. Specifically, when the two viruses spread over possibly different directed infection graphs, the system may have the following: first, a unique equilibrium, the healthy state, which is globally stable, implying that both viruses will eventually be eradicated, second, two equilibria including the healthy state and a dominant virus state, which is almost globally stable, implying that one virus will pervade the entire network causing a single-virus epidemic while the other virus will be eradicated, or third, at least three equilibria including the healthy state and two dominant virus states, depending on certain conditions on the healing and infection rates. When the two viruses spread over the same directed infection graph, the system may have zero or infinitely many coexisting epidemic equilibria, which represents the pervasion of the two viruses. Sensitivity properties of some nontrivial equilibria are investigated in the context of a decentralized control technique, and an impossibility result is given for a certain type of distributed feedback controller.",

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author = "Ji Liu and Pare, {Philip E.} and Angelia Nedich and Tang, {Choon Yik} and Beck, {Carolyn L.} and Tamer Basar",

note = "Funding Information: Manuscript received June 17, 2017; revised March 9, 2018, August 8, 2018, and January 5, 2019; accepted January 27, 2019. Date of publication February 11, 2019; date of current version December 3, 2019. This work was supported in part by the National Science Foundation under Grant ECCS 15-09302, Grant CCF 11-11342, Grant DMS 13-12907, and Grant CNS 15-44953; in part by the Office of Naval Research MURI under Grant N00014-16-1-2710; in part by the U.S. Army Research Office under Grant W911NF-16-1-0485; and in part by the Office of Naval Research, Basic Research under Grant Navy N00014-12-1-0998. This paper was presented in part at 55th IEEE Conference on Decision and Control, Las Vegas, NV, USA, December, 2016 [1]. Recommended by Associate Editor M. Cao. (Corresponding author: Philip E. Par{\'e}.) J. Liu is with the Department of Electrical and Computer Engineering, Stony Brook University, Centereach, NY 11720 USA (e-mail:,ji.liu@ stonybrook.edu). Publisher Copyright: {\textcopyright} 1963-2012 IEEE.",

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N1 - Funding Information: Manuscript received June 17, 2017; revised March 9, 2018, August 8, 2018, and January 5, 2019; accepted January 27, 2019. Date of publication February 11, 2019; date of current version December 3, 2019. This work was supported in part by the National Science Foundation under Grant ECCS 15-09302, Grant CCF 11-11342, Grant DMS 13-12907, and Grant CNS 15-44953; in part by the Office of Naval Research MURI under Grant N00014-16-1-2710; in part by the U.S. Army Research Office under Grant W911NF-16-1-0485; and in part by the Office of Naval Research, Basic Research under Grant Navy N00014-12-1-0998. This paper was presented in part at 55th IEEE Conference on Decision and Control, Las Vegas, NV, USA, December, 2016 [1]. Recommended by Associate Editor M. Cao. (Corresponding author: Philip E. Paré.) J. Liu is with the Department of Electrical and Computer Engineering, Stony Brook University, Centereach, NY 11720 USA (e-mail:,ji.liu@ stonybrook.edu). Publisher Copyright: © 1963-2012 IEEE.

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AB - This paper studies a distributed continuous-time bi-virus model in which two competing viruses spread over a network consisting of multiple groups of individuals. Limiting behaviors of the network are characterized by analyzing the equilibria of the system and their stability. Specifically, when the two viruses spread over possibly different directed infection graphs, the system may have the following: first, a unique equilibrium, the healthy state, which is globally stable, implying that both viruses will eventually be eradicated, second, two equilibria including the healthy state and a dominant virus state, which is almost globally stable, implying that one virus will pervade the entire network causing a single-virus epidemic while the other virus will be eradicated, or third, at least three equilibria including the healthy state and two dominant virus states, depending on certain conditions on the healing and infection rates. When the two viruses spread over the same directed infection graph, the system may have zero or infinitely many coexisting epidemic equilibria, which represents the pervasion of the two viruses. Sensitivity properties of some nontrivial equilibria are investigated in the context of a decentralized control technique, and an impossibility result is given for a certain type of distributed feedback controller.

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Analysis and Control of a Continuous-Time Bi-Virus Model

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